KR810001184B1 - Electron gun assembly - Google Patents

Abstract

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Description

Electron gun assembly

1 is a partial cross-sectional view of an in-line electron gun assembly.

2 is a graph showing the relationship between the burn time and the breaking voltage for three electron guns of the conventional electron gun assembly.

3 is a graph showing the relationship between the heating time and the breaking voltage for three electron guns of the temperature-compensated electron gun assembly according to the present invention.

The present invention relates to an electron gun assembly, and more particularly, to an electron gun assembly for use in color television receivers.

A phosphor consisting of three separate cathodes, a control grid (hereinafter referred to as a first grid) spaced from the cathode at regular intervals, and a screen-in grid (hereinafter referred to as a second grid) spaced from the control grid at regular intervals. In the line electron gun assembly, separate bias voltages are applied to the cathode. These bias voltages applied to the cathode are adjusted by simultaneously blocking the beam current for black level adjustment. The voltage of the first grid is at approximately 0V and the voltage value adjusted for the second grid is provided to establish the cathode cutoff bias voltage within the range of approximately 100V to 150V.

In a typical setup for operating a water tube, an appropriate level of video drive signal can be used to track from black level to all levels of standard white picture over a dynamic range of useful pictures. Applied to wood. In good tube operation, three electron guns are maintained in the tracking of the white picture, with this setup maintaining an even blocking relationship.

However, in the prior art, there is a drawback that the desired uniformity of the blocking relationship on heating is not maintained and that the filament is maintained evenly after about 15 minutes after heating, which is caused by the heating of the cathode and the related structure. This is because the spacing varies between the cathode and the first grid. The spacing between the cathode and the first grid is the most important factor in establishing the barrier, and if both the spacing between the cathode and the first grid match, they must be extended evenly in size and time.

The gun assembly of the present invention, as well as the gun gun assembly of the prior art, consists of at least two or more cathodes, which are designed to maintain a constant distance from the common control grid by means of separate cathode supports. Depending on the temperature function of each cathode support, one of the cathode supports is stabilized under higher operating temperature conditions than the other support. However, the electron gun assembly according to the present invention keeps the change in temperature between the cathode and the control grid substantially equal between the cathodes.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 shows a portion of an electron gun assembly 10 used in a color television receiver, where a conventional electron gun assembly and a temperature-compensated electron gun assembly according to the present invention have the same structure except that different materials are used. It is. In other words, the structure shown in FIG. 1 is a structure applicable to both new and old electron gun structures.

The electron gun assembly 10 consists of a central cathode 12, a first external cathode 14 and a second external cathode 16, the central cathode 12 being coated at its tip with an electron emitting material. And a cathode sleeve 18 adjacent the front end of the cap 20 having one end coating 22. The filament 23 is installed inside the cathode sleeve 18. The coating 22 of electron-emitting material is held at regular intervals from the first grid 28, which is attached to the fixed center cathode support 26 and the cathode sleeve 18 which is attached to the cathode sleeve 18. eyelet) is held at about 0.13 mm intervals when assembled.

Similarly, the first and second outer cathodes 14 and 16 also include a cathode sleeve 30 adjacent the front end of the cap 32, which cap 32 has an electron emitting material thereon. The tip coating portion 34 with the tip coating is contained. Filament 35 is also installed inside each cathode sleeve 30. Coatings 34 of electron-emitting materials are each held at regular intervals from the first grid 28 by the cathode arret 36, the cathode eyelets 36 having a fixed outer cathode support 38 Is attached to the cathode sleeve 30 as well. The outer cathode spacing is also established during assembly, maintaining approximately 0.13 mm spacing, equal to the spacing of the central cathodes.

In the gun gun assembly of the prior art, all three cathode eyelets are made of the same material (i.e. 52 metal, usually an alloy of 48% nickel 52% iron), which has the advantage of relatively low thermal expansion. . The two cathode support structures 26 and 38 are of different thicknesses, for example, the outer support structure 38 is formed to be 0.51 mm thick to maintain the strength of the structure, while the central support structure 26 is Is formed to a thickness of 0.25 mm to maintain adequate spacing between the center and outer cathodes. Since the thicker outer support structure 38 provides a better path for conducting heat out of the filament than the thinner central support structure 26, thermal equilibrium is achieved about 15 minutes after the filament is heated. The central cathode 12 then operates at a higher temperature than the other two outer cathodes 14 and 16. In other words, the temperature rise of the central cathode upon heating is greater than the temperature rise of the outer cathodes 14, 16.

As a result of the rise in temperature upon heating, the cathode sleeves 18 and 30 expand toward the control grid 28 in the direction indicated by arrow 40, while the cathode eyelets 24 and 36 are arrowed. In the direction indicated by 42, the control grid 28 is expanded in the opposite direction. This unevenness in the flat window and temperature rise of the cathode sleeves and eyelets causes a gap between the cathode and the control grid, resulting in a change in the uniform gap initially established during assembly.

Because of the relatively thin bricks of the cathode, close to the filament, and good thermoelectric separation from the rest of the electron gun assembly, the cathode sleeves 18, 30 are typically used after the filaments have been heated for the structure shown in FIG. The thermal equilibrium is achieved in a relatively short time within 30 seconds. In other words, after 30 seconds the thermal expansion of the cathode sleeve is minimal. As a result, after approximately the first heating time, the main reason for the change in the spacing between the cathode and the control grid is due to the expansion of the cathode eyelets 24 and 36.

As mentioned above, it is generally believed that the spacing between the cathode and the control grid is the most important factor in establishing the interruption. Recognizing that a change in the spacing between the cathode and the control grid occurs upon heating, the blocking bias voltage is not established until the operating temperature equilibrium is achieved over as little as 5 minutes, preferably over 15 minutes, after the filament has been heated. This bias voltage is adjusted to compensate for the gap between the non-uniform cathode and the grid, allowing the three electron guns to maintain a generally uniform blocking relationship after the filament is heated.

Since the bias voltage once established does not change, compensating for the bias voltage when the spacing between the first grease and the cathode is approximately equal causes an uneven blocking relationship between the central electron gun and the external electron gun. As the temperature of the cathode increases, this inequality in the blocking relationship is reduced until equilibrium is established again at operating temperature equilibrium.

Curve 50 in FIG. 2 shows the relationship between the cut-off voltage applied to the first grid and the heating time for the central cathode. Similarly, curve 52 shows the relationship between the cut-off voltage and heating time for one of the external cathodes, and curve 54 shows the relationship between the cut-off voltage and heating time for the first grid supplied to the other external cathodes. .

The cutoff voltage (curve 50) for the central cathode 1 minute after the filament has been heated is about 4.5 volts less than the cutoff voltages (curves 52 and 54) for the outer cathodes. After 10 minutes of heating the filament, the breaking voltage is approximately equal. Using the Sensitivity factor, which has been determined to be 14 volts for a distance of 0.025 mm between the cathode and the first grid for the shape of the electron gun assembly shown in FIG. 1, the curve shown in FIG. In minutes, the central cathode expands about 0.08 mm more from the first grid than the outer cathode. As mentioned above, since this period under consideration takes place for one minute after the filament has been heated, it can be seen that almost all of these changes in spacing are due to the expansion of the cathode eyelets.

In order to correct the blocking tracking problem caused by heating as described above, the outer cathode eyelet 36 is made of a material having a higher coefficient of thermal expansion than the material used to make the central cathode eyelet 24. Fabrication, which causes the outer cathode eyelet 36 and the central eyelet 24 to expand at the same rate, so that the change in spacing between the cathode first grid is substantially equal between the electron guns and is substantially even The blocking relationship is to be maintained upon heating.

Temperature measurement of the outer eyelet 36 in the structure of FIG. 1 shows that the filament has risen to 120 ° C. for 9 minutes between 1 and 10 minutes after heating. Since the central eyelet expands 0.008 mm more than the outer cathode eyelets in a conventional structure, the outer eyelet may be made of a material that expands about 0.00 mm more than the outer cathode eyelet material at 120 ° C. Alternatively, it is possible to select a material for the center cathode eyelet that reduces the center eyelet by about 0.008 mm, but the first method to consider is that the temperature change in the spacing between the cathode and the first grid is substantially equal. Because it is.

A good material for the outer cathode eyelet 36 for the electron gun assembly 10 in which the center cathode eyelet 24 is made of 52 metal is 305 having a thermal expansion coefficient of 20 [μ] at 1 m per centigrade. Stainless steel material is good. In a conventional structure in which all three cathode eyelets were made in a 52 metal form with a coefficient of thermal expansion of 9.5 [μ] for 1 meter per centigrade, each outer cathode eyelet 36 was 1 minute after the filament was heated. The outer cathode eyelet 36, made from 305 stainless steel material according to the invention, expands about 6.35 mm to a nominal length of 6.35 mm in 10 minutes at 10 minutes. about 0.015 mm swell to mm. As a result, the thermal expansion of the outer cathode eyelet according to the present invention expands 0.008 mm more than the external cathode thermal expansion according to the prior art, so that the thermal expansion of the central cathode eyelet 24 and the center portion are equal.

FIG. 3 shows the relationship between heating time and breaking voltage for an electron gun assembly composed of a central cathode eyelet 24 made of 52 metal and an external cathode eyelet 36 made of 305 stainless steel. Looking at the drawing, the curve 50 is a curve for the central cathode, and because it is made of the same material as the conventional material, it can be interpreted as the curve 50 of FIG. 2, but two curves for two external cathodes. (52) (54) is different from the curved form of FIG. 2 because it is made of 305 stainless steel which features the present invention. As shown, approximately one minute after the filament has been heated, the blocking voltage applied to the first grid for all three cathodes is generally equal, which is caused by the material selected for the cathode eyelet. This is because it causes a change in temperature between the wood and the first grid to be substantially equal between the cathodes. This practical equality of the cutoff voltage during the heating time practically eliminates the undesirable dominance of the color caused by the central cathode so that white picture tracking is maintained.

Claims (1)

Each of the cathodes 12, 14 (in an electron gun assembly 10 having a central cathode 12 disposed in a co-planar relationship between two outer cathodes 14, 16) ( 16 is maintained at a constant distance from the common control grid 28 by separate cathode supports 26, 38, each of which is a function of the temperature of each cathode support 26, 38. As shown in FIG. In the electron gun assembly, wherein each support 26 of the cathode supports 26, 38 is stabilized under higher operating temperature conditions than the other cathode support 38, each cathode 12, 14 Electron gun assembly, characterized in that the change in temperature at each interval between the (16) and the first grid (28) remains substantially the same between each cathode.

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